Hint: The de-Broglie wavelength depends on the momentum of the particle.

Step 1: Conserve the momentum.

As collision is elastic, hence laws of conservation of momentum and kinetic energy are obeyed. 

According to the law of conservation of momentum, 

$m_{A}v+m_B\times 0=m_A{v}_1+m_B{v}_2$
$\Rightarrow m_A (v-v_1)=m_B{v}_2$

Step 2: Conserve the kinetic energy.

According to the law of conservation of kinetic energy,

$\begin{array}{rl}\frac{1}{2}{m}_A{v}^2& =\frac{1}{2}{m}_A{v}_1^2+\frac{1}{2}{m}_B{v}_2^2 ...\left(i\right)\\ \Rightarrow m_A(v-v_1^2)& =m_8{v}_2^2\\ \Rightarrow m_A(v-v_1)(v+v_1)& =m_B{v}_2^2 ...\left(ii\right)\end{array}$

Step 3: Find the final velocities of A and B.

Dividing Eq. (ii) by Eq. (i) ;

we get,     $v+v_1=v_2 or v=v_2-v_1 ...\left(iii\right)$

Step 4: Find the change in wavelength of particle A.

Solving Eqs. (i) and (ii), we get;

                          $v_1=\left(\frac{m_A-m_B}{m_A+m_B}\right)v and v_2=\left(\frac{2m_A}{m_A+m_B}\right)$
${\lambda }_{initial }=\frac{h}{m_{A}v}$
${\lambda }_{final }=\frac{h}{m_A{v}_1}=\frac{h(m_A+m_B)}{m_A(m_A-m_B)v}$
$∆\lambda ={\lambda }_{final }-{\lambda }_{initial }=\frac{h}{m_{A}v}\left[\frac{m_A+m_B}{m_A-m_B}-1\right]$